KR20210081423A - Exhaust gas aftertreatment device, exhaust gas aftertreatment system - Google Patents

Abstract

The present invention comprises one or more channels 14 for guiding the aqueous urea solution; An exhaust gas aftertreatment device (3) for an automobile internal combustion engine has a housing (6) comprising a chamber (15) arranged therein with a controllable actuator (11) operable to guide the urea solution, wherein the chamber (3) is provided. 15 comprises one or more ammonia protection devices 21 for protecting one or more components, in particular the actuator 11 from ammonia diffusion. The ammonia protection device (21) comprises in the housing (6) one or more openings (18), which are closed by a gas-permeable membrane (20) and are assigned to the chamber (15).

Description

Exhaust gas aftertreatment device, exhaust gas aftertreatment system

The present invention provides one or more channels for guiding an aqueous solution of urea; An exhaust gas aftertreatment device for a motor vehicle internal combustion engine comprising a chamber arranged therein with a controllable actuator acting on the guidance of the urea solution, wherein the chamber is configured to remove one or more components, in particular the actuators, from ammonia diffusion. at least one ammonia protection device for protection.

In today's exhaust gas aftertreatment systems, an aqueous urea solution is typically used as a reactant for exhaust gas aftertreatment. It is, for example, stored in a tank and fed by means of a conveying device to a metering feed valve, where the aqueous urea solution reacts with the exhaust gas downstream of the injection point, in particular in the catalytic converter provided for this, to reduce emissions The urea aqueous solution is sprayed to the exhaust pipe of the internal combustion engine as needed. Both the conveying device and the metering supply valve each represent an exhaust gas aftertreatment agent treatment device of the exhaust gas aftertreatment system. They both guide the aqueous urea solution and comprise a chamber in which an actuator is arranged, for example for actuation of a valve member or a pump piston. Ammonia from the aqueous urea solution can diffuse into the chamber, where it acts erosively, in particular on the components of the actuator, whereby these components corrode, for example, particularly rapidly. To prevent this, it is known to provide an ammonia protection device in such a chamber, for example formed as a silver coating of the electrical connection contact of the actuator. Shielding of endangered components can also be achieved by more expensive means, for example complex housing parts and/or seals. However, this also results in high manufacturing costs as each individual component is provided with its own ammonia protection device.

The exhaust gas aftertreatment device having the features of claim 1 has the advantage that, through a simple and inexpensive solution, all components located in the chamber, in particular at risk of the actuator, can be protected from ammonia. In this case, protection can be achieved simply and inexpensively, in particular since the individual components of the actuator do not have to be treated or protected separately. According to the invention, this is achieved in that the ammonia protection device comprises in the housing at least one opening assigned to the chamber and closed by a gas-permeable membrane. These openings ensure pressure compensation inside the housing, ie between the chamber and the periphery. With the membrane it is achieved that pressure compensation can only be effected via gas exchange. This gas exchange allows gaseous ammonia to diffuse out of the chamber through the membrane, and thus cannot reach concentrations in the chamber that are a threat to components located within the chamber. This ensures that all components located in the chamber, of the exhaust gas aftertreatment device and in particular of the actuator, are reliably protected from ammonia via the at least one opening and the membrane. In particular, this exhaust gas aftertreatment device is an exhaust gas aftertreatment device that closes the flow section for the aqueous urea solution in the absence of current or in the absence of current. In this state, as the diffusion of ammonia from the urea solution increases, the pressure in the chamber may increase, and the ammonia concentration may reach a critical value. In this very part, it is preferred that a preferred ammonia protection device is present.

Preferably, this opening is formed in the housing cover of the housing. Due to this, the opening can be provided simply in the housing and can also be provided subsequently, for example without impairing the functionality of the exhaust gas aftertreatment device. In particular, by providing an opening in the housing cover, it is ensured that the membrane is also already assembled into the cover prior to assembly of the cover, in order to make it possible to simply assign the ammonia protection device to the chamber. Accordingly, it is particularly advantageous if the membrane is arranged pre-assembled in the housing cover.

Also preferably the membrane lies on the inner side of the housing cover facing the chamber. This ensures a sealed connection between the membrane and the housing cover, assisted by the pressure present in the chamber.

Furthermore, the actuator is preferably configured as an electromagnetic actuator. To this end, there are, for example, one or more current-supplyable coils in the chamber and an armature capable of magnetically interacting with these coils and displaceable.

In particular, the actuator comprises an armature displaceably mounted within the chamber, which armature is connected to the pump piston and/or the valve member for actuation. Thus, the exhaust gas aftertreatment device is configured as, for example, a transfer pump or a metering supply valve.

The exhaust gas aftertreatment system according to the invention having the features of claim 7 is characterized in that at least one exhaust gas aftertreatment device is formed according to the invention. Due to this, the advantages already mentioned are obtained. In addition to the use of exhaust gas aftertreatment systems and/or exhaust gas aftertreatment devices in internal combustion engines, medical technology, coffee machines, thermal technology or other devices where exhaust gases containing reactive substances that pose a threat to individual components are expected. It is also possible to consider using /system.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be explained in more detail below with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a simplified illustration of a preferred exhaust gas aftertreatment system.

1 shows a tank 2 for storing a liquid exhaust gas aftertreatment agent in the form of an aqueous urea solution; An exhaust gas aftertreatment system 1 is shown in simplified illustration comprising an exhaust gas aftertreatment agent treatment device 3 , formed as a transfer pump 4 , fluidically connected with a tank 2 . The transfer pump 4 is connected on the suction side with the tank 2 and on the pressure side with a controllable metering supply valve 5 shown here simply.

The exhaust gas aftertreatment device 3 comprises a housing 6 in which a membrane piston pump 7 is arranged. The membrane piston pump 7 comprises a displaceably mounted pump piston 8 which sucks the exhaust gas aftertreatment from the tank 2 through reciprocating motion and in the direction of the metering supply valve 5 . It interacts with the flexible membrane 9 for transport. Due to this, the membrane piston pump 7 is formed in a known way and manner.

The pump piston 8 is in fixed connection with the armature 10 of the electromagnetic actuator 11 , which is likewise mounted displaceably. The actuator 11 also comprises a coil 12 capable of supplying an electric current, which magnetically interacts with the armature 10 . When the coil 12 is energized, it pulls the armature 10 and thus the piston 8 against the force of the return spring 13 . When the current supply is terminated, the return spring 13 urges the armature 10 and thus the pump piston 8 again to its starting position. In this way, a reciprocating motion of the pump piston 8 is achieved.

Through the pump motion, the aqueous urea solution is transported through channels 14 extending through the housing 6 and interacting with the membrane 9 . The actuator 11 is located in a chamber 15 which is separated from the channel 14 , in particular via a membrane 9 , and since in the chamber 15 in particular a housing element or a guide element is located, this chamber is hatched in this figure. It is shown in a closed state and is generally free of liquid. The housing 6 comprises a housing trough 16 in which an actuator 11 and a pump piston 8 and a membrane 9 are arranged. The housing 6 also includes a housing cover 17 closing the chamber 15 and sealingly connected to the housing trough 16 . The housing cover 17 allows the individual components of the transport device 4 to be simply assembled in the chamber 15 . In particular, the cover 17 is materially connected with the housing trough 16, in particular welded, so that a hermetic connection is permanently ensured.

In the cover 17 , an opening 18 is formed which is arranged opposite to the return spring 13 or the armature 10 on the end side according to the present exemplary embodiment. The opening 18 is closed through the gas permeable membrane 20 on the inner side 19 of the housing cover 17 facing the chamber 15 . Since the membrane 20 abuts the inner side 19 and thus covers the entire opening 18 , gas can only leak out of the chamber 15 through the membrane 20 . The membrane 20 is formed in particular in the form of a pressure compensating membrane.

During operation, when ammonia from a urea solution located in channel 14 diffuses and reaches chamber 15 , gaseous ammonia leaves chamber 15 through membrane 20 and opening 18 . Due to this, it is achieved that a critical concentration of ammonia in the chamber 15 cannot be established, which may in particular affect the components of the actuator 11 . The opening 18 thus forms together with the membrane 20 the ammonia protection device 21 for the exhaust gas aftertreatment agent treatment device 3 . Thereby, permanent and safe operation of the exhaust gas aftertreatment agent treatment device 3 and the exhaust gas aftertreatment system 1 is ensured in a simple and inexpensive way and manner.

Claims (7)

one or more channels (14) for guiding the aqueous urea solution; An exhaust gas aftertreatment device (3) for an automobile internal combustion engine having a housing (6) comprising a chamber (15) arranged therein with a controllable actuator (11) acting on the guidance of a urea solution, the chamber (15) An exhaust gas aftertreatment device comprising at least one ammonia protection device (21) for protecting one or more components, in particular the actuator (11) from ammonia diffusion,
Exhaust gas aftertreatment device, characterized in that the ammonia protection device (21) comprises in the housing (6) at least one opening (18) which is closed by a gas-permeable membrane (20) and is assigned to the chamber (15). Device according to claim 1, characterized in that the opening (18) is formed in the housing cover (17) of the housing (6). 3. Exhaust gas aftertreatment device according to claim 1 or 2, characterized in that the membrane (20) is arranged pre-assembled on the housing cover (17). Device according to one of the preceding claims, characterized in that the membrane (20) abuts the inner side (19) of the housing cover (17) facing the chamber (15). The exhaust gas aftertreatment device according to one of the preceding claims, characterized in that the actuator (11) is configured as an electromagnetic actuator (11). 6. A method according to any one of the preceding claims, wherein the actuator (11) comprises a displaceably mounted armature (10), which is connected to the pump piston (8) and/or the valve member for actuation. Characterized in the exhaust gas after-treatment device. a tank (2) for the provision and storage of an aqueous urea solution; An exhaust gas aftertreatment system (1) for a motor vehicle internal combustion engine having; at least one exhaust gas aftertreatment device (3) fluidly connected to a tank (2),
An exhaust gas aftertreatment system according to any one of the preceding claims, characterized in that at least one exhaust gas aftertreatment device (3) is formed.

Images